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https://github.com/servalproject/serval-dna.git
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2252fdcaa7
OUT()s or where return() is used instead of RETURN(). Added OUT() to end of all functions using IN() that lacked it to make it easier to statically analyse this invariant. Fixed several return instead of RETURNs detected through use of this tool. #49
414 lines
13 KiB
C
414 lines
13 KiB
C
/*
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Serval Distributed Numbering Architecture (DNA)
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Copyright (C) 2010 Paul Gardner-Stephen
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License
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as published by the Free Software Foundation; either version 2
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of the License, or (at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*/
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/*
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Smart-flooding of broadcast information is also a requirement. The long addresses help here, as we can make any address that begins
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with the first 192 bits all ones be broadcast, and use the remaining 64 bits as a "broadcast packet identifier" (BPI).
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Nodes can remember recently seen BPIs and not forward broadcast frames that have been seen recently. This should get us smart flooding
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of the majority of a mesh (with some node mobility issues being a factor). We could refine this later, but it will do for now, especially
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since for things like number resolution we are happy to send repeat requests.
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*/
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#include "serval.h"
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#include "conf.h"
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#include "str.h"
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#include "overlay_address.h"
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#include "overlay_buffer.h"
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#include "overlay_packet.h"
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#include <arpa/inet.h>
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#define MAX_BPIS 1024
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#define BPI_MASK 0x3ff
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static struct broadcast bpilist[MAX_BPIS];
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#define OA_CODE_SELF 0xff
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#define OA_CODE_PREVIOUS 0xfe
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// each node has 16 slots based on the next 4 bits of a subscriber id
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// each slot either points to another tree node or a struct subscriber.
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struct tree_node{
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// bit flags for the type of object each element points to
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int is_tree;
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union{
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struct tree_node *tree_nodes[16];
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struct subscriber *subscribers[16];
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};
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};
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static struct tree_node root;
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struct subscriber *my_subscriber=NULL;
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static unsigned char get_nibble(const unsigned char *sid, int pos){
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unsigned char byte = sid[pos>>1];
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if (!(pos&1))
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byte=byte>>4;
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return byte&0xF;
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}
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// find a subscriber struct from a whole or abbreviated subscriber id
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struct subscriber *find_subscriber(const unsigned char *sid, int len, int create){
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struct tree_node *ptr = &root;
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int pos=0;
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if (len!=SID_SIZE)
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create =0;
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do{
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unsigned char nibble = get_nibble(sid, pos++);
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if (ptr->is_tree & (1<<nibble)){
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ptr = ptr->tree_nodes[nibble];
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}else if(!ptr->subscribers[nibble]){
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// subscriber is not yet known
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if (create){
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struct subscriber *ret=(struct subscriber *)malloc(sizeof(struct subscriber));
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memset(ret,0,sizeof(struct subscriber));
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ptr->subscribers[nibble]=ret;
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bcopy(sid, ret->sid, SID_SIZE);
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ret->abbreviate_len=pos;
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}
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return ptr->subscribers[nibble];
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}else{
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// there's a subscriber in this slot, does it match the rest of the sid we've been given?
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struct subscriber *ret = ptr->subscribers[nibble];
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if (memcmp(ret->sid,sid,len)==0){
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return ret;
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}
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// if we need to insert this subscriber, we have to make a new tree node first
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if (!create)
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return NULL;
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// create a new tree node and move the existing subscriber into it
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struct tree_node *new=(struct tree_node *)malloc(sizeof(struct tree_node));
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memset(new,0,sizeof(struct tree_node));
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ptr->tree_nodes[nibble]=new;
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ptr->is_tree |= (1<<nibble);
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ptr=new;
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nibble=get_nibble(ret->sid,pos);
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ptr->subscribers[nibble]=ret;
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ret->abbreviate_len=pos+1;
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// then go around the loop again to compare the next nibble against the sid until we find an empty slot.
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}
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}while(pos < len*2);
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// abbreviation is not unique
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return NULL;
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}
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/*
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Walk the subscriber tree, calling the callback function for each subscriber.
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if start is a valid pointer, the first entry returned will be after this subscriber
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if the callback returns non-zero, the process will stop.
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*/
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static int walk_tree(struct tree_node *node, int pos,
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unsigned char *start, int start_len,
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unsigned char *end, int end_len,
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int(*callback)(struct subscriber *, void *), void *context){
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int i=0, e=16;
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if (start && pos < start_len*2){
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i=get_nibble(start,pos);
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}
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if (end && pos < end_len*2){
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e=get_nibble(end,pos) +1;
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}
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for (;i<e;i++){
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if (node->is_tree & (1<<i)){
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if (walk_tree(node->tree_nodes[i], pos+1, start, start_len, end, end_len, callback, context))
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return 1;
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}else if(node->subscribers[i]){
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if (callback(node->subscribers[i], context))
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return 1;
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}
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// stop comparing the start sid after looking at the first branch of the tree
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start=NULL;
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}
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return 0;
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}
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/*
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walk the tree, starting at start inclusive, calling the supplied callback function
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*/
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void enum_subscribers(struct subscriber *start, int(*callback)(struct subscriber *, void *), void *context){
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walk_tree(&root, 0, start->sid, SID_SIZE, NULL, 0, callback, context);
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}
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// generate a new random broadcast address
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int overlay_broadcast_generate_address(struct broadcast *addr)
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{
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int i;
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for(i=0;i<BROADCAST_LEN;i++) addr->id[i]=random()&0xff;
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return 0;
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}
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// test if the broadcast address has been seen
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int overlay_broadcast_drop_check(struct broadcast *addr)
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{
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/* Hash the BPI and see if we have seen it recently.
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If so, drop the frame.
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The occassional failure to supress a broadcast frame is not
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something we are going to worry about just yet. For byzantine
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robustness it is however required. */
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int bpi_index=0;
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int i;
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for(i=0;i<BROADCAST_LEN;i++)
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{
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bpi_index=((bpi_index<<3)&0xfff8)+((bpi_index>>13)&0x7);
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bpi_index^=addr->id[i];
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}
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bpi_index&=BPI_MASK;
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if (memcmp(bpilist[bpi_index].id, addr->id, BROADCAST_LEN)){
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if (config.debug.broadcasts)
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DEBUGF("BPI %s is new", alloca_tohex(addr->id, BROADCAST_LEN));
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bcopy(addr->id, bpilist[bpi_index].id, BROADCAST_LEN);
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return 0; /* don't drop */
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}else{
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if (config.debug.broadcasts)
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DEBUGF("BPI %s is a duplicate", alloca_tohex(addr->id, BROADCAST_LEN));
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return 1; /* drop frame because we have seen this BPI recently */
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}
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}
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int overlay_broadcast_append(struct overlay_buffer *b, struct broadcast *broadcast)
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{
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return ob_append_bytes(b, broadcast->id, BROADCAST_LEN);
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}
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// append an appropriate abbreviation into the address
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int overlay_address_append(struct decode_context *context, struct overlay_buffer *b, struct subscriber *subscriber)
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{
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if (!subscriber)
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return WHY("No address supplied");
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if (context && subscriber==context->sender){
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if (ob_append_byte(b, OA_CODE_SELF))
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return -1;
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}else if(context && subscriber==context->previous){
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if (ob_append_byte(b, OA_CODE_PREVIOUS))
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return -1;
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}else{
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int len=SID_SIZE;
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if (subscriber->send_full){
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subscriber->send_full=0;
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}else{
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len=(subscriber->abbreviate_len+2)/2;
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if (subscriber->reachable==REACHABLE_SELF)
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len++;
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if (len>SID_SIZE)
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len=SID_SIZE;
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}
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if (ob_append_byte(b, len))
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return -1;
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if (ob_append_bytes(b, subscriber->sid, len))
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return -1;
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}
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if (context)
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context->previous = subscriber;
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return 0;
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}
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static int add_explain_response(struct subscriber *subscriber, void *context){
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struct decode_context *response = context;
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if (!response->please_explain){
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response->please_explain = calloc(sizeof(struct overlay_frame),1);
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response->please_explain->payload=ob_new();
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ob_limitsize(response->please_explain->payload, 1024);
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}
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// if one of our identities is unknown,
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// the header of this packet must include our full sid.
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if (subscriber->reachable==REACHABLE_SELF){
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subscriber->send_full=1;
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if (subscriber==my_subscriber){
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response->please_explain->source_full=1;
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return 0;
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}
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}
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// add the whole subscriber id to the payload, stop if we run out of space
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DEBUGF("Adding full sid by way of explanation %s", alloca_tohex_sid(subscriber->sid));
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if (ob_append_byte(response->please_explain->payload, SID_SIZE))
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return 1;
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if (ob_append_bytes(response->please_explain->payload, subscriber->sid, SID_SIZE))
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return 1;
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return 0;
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}
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static int find_subscr_buffer(struct decode_context *context, struct overlay_buffer *b, int len, struct subscriber **subscriber){
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if (len<=0 || len>SID_SIZE){
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return WHY("Invalid abbreviation length");
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}
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unsigned char *id = ob_get_bytes_ptr(b, len);
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if (!id){
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return WHY("Not enough space in buffer to parse address");
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}
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if (!subscriber){
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WARN("Could not resolve address, no buffer supplied");
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context->invalid_addresses=1;
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return 0;
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}
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*subscriber=find_subscriber(id, len, 1);
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if (!*subscriber){
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context->invalid_addresses=1;
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// generate a please explain in the passed in context
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// add the abbreviation you told me about
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if (!context->please_explain){
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context->please_explain = calloc(sizeof(struct overlay_frame),1);
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context->please_explain->payload=ob_new();
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ob_limitsize(context->please_explain->payload, MDP_MTU);
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}
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// And I'll tell you about any subscribers I know that match this abbreviation,
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// so you don't try to use an abbreviation that's too short in future.
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walk_tree(&root, 0, id, len, id, len, add_explain_response, context);
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INFOF("Asking for explanation of %s", alloca_tohex(id, len));
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ob_append_byte(context->please_explain->payload, len);
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ob_append_bytes(context->please_explain->payload, id, len);
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}else{
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if (context)
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context->previous=*subscriber;
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}
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return 0;
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}
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int overlay_broadcast_parse(struct overlay_buffer *b, struct broadcast *broadcast)
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{
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return ob_get_bytes(b, broadcast->id, BROADCAST_LEN);
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}
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// returns 0 = success, -1 = fatal parsing error, 1 = unable to identify address
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int overlay_address_parse(struct decode_context *context, struct overlay_buffer *b, struct subscriber **subscriber)
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{
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int len = ob_get(b);
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if (len<0)
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return WHY("Buffer too small");
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switch(len){
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case OA_CODE_SELF:
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if (!context->sender){
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INFO("Could not resolve address, sender has not been set");
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context->invalid_addresses=1;
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}else{
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*subscriber=context->sender;
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context->previous=context->sender;
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}
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return 0;
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case OA_CODE_PREVIOUS:
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if (!context->previous){
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INFO("Unable to decode previous address");
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context->invalid_addresses=1;
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}else{
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*subscriber=context->previous;
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}
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return 0;
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}
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return find_subscr_buffer(context, b, len, subscriber);
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}
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// once we've finished parsing a packet, complete and send a please explain if required.
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int send_please_explain(struct decode_context *context, struct subscriber *source, struct subscriber *destination){
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IN();
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struct overlay_frame *frame=context->please_explain;
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if (!frame)
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RETURN(0);
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frame->type = OF_TYPE_PLEASEEXPLAIN;
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if (source)
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frame->source = source;
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else
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frame->source = my_subscriber;
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if (!context->sender)
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frame->source_full=1;
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frame->source->send_full=1;
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frame->destination = destination;
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if (destination && (destination->reachable & REACHABLE)){
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frame->ttl=64;
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}else{
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frame->ttl=1;// how will this work with olsr??
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overlay_broadcast_generate_address(&frame->broadcast_id);
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if (context->interface){
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frame->destination_resolved=1;
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frame->next_hop = destination;
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frame->recvaddr = context->addr;
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frame->interface = context->interface;
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}
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}
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frame->queue=OQ_MESH_MANAGEMENT;
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if (!overlay_payload_enqueue(frame))
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RETURN(0);
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op_free(frame);
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RETURN(-1);
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OUT();
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}
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// process an incoming request for explanation of subscriber abbreviations
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int process_explain(struct overlay_frame *frame){
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struct overlay_buffer *b=frame->payload;
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struct decode_context context;
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bzero(&context, sizeof context);
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while(ob_remaining(b)>0){
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int len = ob_get(b);
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if (len<=0 || len>SID_SIZE)
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return WHY("Badly formatted explain message");
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unsigned char *sid = ob_get_bytes_ptr(b, len);
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if (!sid)
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return WHY("Ran past end of buffer");
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if (len==SID_SIZE){
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// This message is also used to inform people of previously unknown subscribers
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// make sure we know this one
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find_subscriber(sid,len,1);
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}else{
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// reply to the sender with all subscribers that match this abbreviation
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INFOF("Sending responses for %s", alloca_tohex(sid, len));
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walk_tree(&root, 0, sid, len, sid, len, add_explain_response, &context);
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}
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}
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send_please_explain(&context, frame->destination, frame->source);
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return 0;
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}
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